Search for a Light Higgs Boson Decaying to Long Lived Weakly Interacting Particles in Proton Proton Collisions at root s=7 TeV with the ATLAS Detector

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(1)PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. Search for a Light Higgs Boson Decaying pffiffiffi to Long-Lived Weakly Interacting Particles in Proton-Proton Collisions at s ¼ 7 TeV with the ATLAS Detector G. Aad et al.* (ATLAS Collaboration) (Received 6 March 2012; published 19 June 2012) A search for the decay of a light Higgs boson (120–140 GeV) to a pair of weakly interacting, long-lived pffiffiffi particles in 1:94 fb1 of proton-proton collisions at s ¼ 7 TeV recorded in 2011 by the ATLAS detector is presented. The search strategy requires that both long-lived particles decay inside the muon spectrometer. No excess of events is observed above the expected background and limits on the Higgs boson production times branching ratio to weakly interacting, long-lived particles are derived as a function of the particle proper decay length. DOI: 10.1103/PhysRevLett.108.251801. PACS numbers: 14.80.Ec, 12.60.i, 13.85.Rm. A Higgs boson [1–3] below 140 GeV is particularly sensitive to new physics. Many extensions of the standard model (SM) include neutral, weakly coupled particles that can be long lived [4,5] and to which the Higgs boson may decay. These long-lived particles occur in many models, including gauge-mediated extensions of the minimal supersymmetric standard model [6], minimal supersymmetric standard model with R-parity violation [7], inelastic dark matter [8], and the hidden valley (HV) scenario [9]. This Letter presents the first ATLAS search for the Higgs boson decay, h0 ! v v , to two identical neutral particles (v ) that have a displaced decay to fermionantifermion pairs. As a benchmark, we take a HV model [9] in which the SM is weakly coupled, by a heavy communicator particle, to a hidden sector that includes a pseudoscalar, the v . Because of the helicity suppression of pseudoscalar decays to low-mass ff pairs, the v decays cc, and þ in the predominantly to heavy fermions, bb, ratio 85:5:8%. The weak coupling between the two sectors leads the v to have a long lifetime. Other, non-HV, models with the identical signature, where the v is replaced with another weakly interacting scalar or pseudoscalar particle, are discussed in Refs. [4,10]. Both Tevatron experiments, CDF and D0, performed similar searches for displaced decays in their respective tracking volumes, which limited the proper decay length range they could explore to a few hundred millimeters [11,12]. In many of these beyond-the-SM scenarios, the lifetime of the neutral states is not specified and can have a very large range. The current search covers a range of expected proper decay lengths extending to about 20 m by exploiting the size and layout of the ATLAS muon spectrometer.. *Full author list given at the end of the article. Published by the American Physical Society under the terms of the Creative Commons Attribution 3.0 License. Further distribution of this work must maintain attribution to the author(s) and the published article’s title, journal citation, and DOI.. 0031-9007=12=108(25)=251801(18). Consequently the experimental challenge is to develop signature-driven triggers to select displaced decays throughout the ATLAS detector volume [13]. This analysis requires both v decays to occur near the outer radius of the hadronic calorimeter (r 4 m) or in the muon spectrometer (MS). Such decays give a (; ) cluster of charged and neutral hadrons in the MS. Requiring both v ’s to have this decay topology improves background rejection. The analysis uses specialized tracking and vertex reconstruction algorithms, described below, to reconstruct vertices in the MS. The analysis strategy takes advantage of the kinematics of the gluon fusion production mechanism and subsequent two-body decay, h0 ! v v , which results in events with back-to-back v ’s, by requiring two well-separated vertices [R pffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi ffi ðÞ2 þ ðÞ2 > 2] [14] in the MS. The data used in this analysis were collected in the first half of 2011 with the LHC operating at 7 TeV. Applying beam, detector, and data quality requirements resulted in a total integrated luminosity of 1:94 fb1 . The integrated luminosity has a relative uncertainty of 3.7% [15,16]. Signal Monte Carlo (MC) samples were generated using PYTHIA [17,18] to simulate gluon fusion production (gg ! h0 ) and the decay of the Higgs boson (h0 ! v v ). Four samples were generated: mh0 ¼ 120 and 140 GeV and for each mh0 , two v masses of 20 and 40 GeV. The predicted Higgs boson production cross sections [19] are ðmh0 ¼ 120 GeVÞ ¼ 16:6þ3:3 2:5 pb and þ2:3 (mh0 ¼ 140 GeVÞ ¼ 12:11:8 pb, and the branching ratio (BR) for h0 ! v v is assumed to be 100%. The response of the ATLAS detector was modeled with GEANT4 [20,21]. The effect of multiple pp collisions occurring during the same bunch crossing (pileup) was simulated by superimposing several minimum bias events on the signal event. The MC events were weighted so that the pileup in the simulation agrees with pileup conditions found in data. ATLAS is a multipurpose detector [22] consisting of an inner tracking detector (ID) surrounded by a superconducting. 251801-1. Ó 2012 CERN, for the ATLAS Collaboration.

(2) week ending 22 JUNE 2012. solenoid that provides a 2 T field, electromagnetic and hadronic calorimeters and a MS with a toroidal magnetic field. The ID, consisting of silicon pixel and strip detectors and a straw tube tracker, provides precision tracking of charged particles for j j 2:5. The calorimeter system covers j j 4:9 and has 9.7 interaction lengths at ¼ 0. The MS consists of a barrel and two forward spectrometers, each with 16 sectors instrumented with detectors for first level triggering and precision tracking detectors for muon momentum measurement. Each spectrometer has three stations along the muon flight path: inner, middle, and outer. In the barrel, the stations are located at radii of 4:5, 7, and 10 m, while in the forward MS, they are located at j z j 7:5, 14, and 20 m. This analysis uses muon tracking for j j 2:4, where each station is instrumented with two multilayers of precision tracking chambers, monitored drift tubes (MDTs). It also utilizes level 1 [23] (L1) muon triggering in the barrel MS ( j j 1). The trigger chambers are located in the middle and outer stations. The L1 muon trigger requires hits in the middle station to create a low pT muon region of interest (RoI) or hits in both the middle and outer stations for a high pT RoI. The muon RoIs have a spacial extent of 0:2 0:2 in and are limited to two RoIs per sector. A dedicated, signature-driven trigger, the muon RoI cluster trigger [13], was developed to trigger on events with a v decaying in the MS. It selects events with a cluster of three or more muon RoIs in a R ¼ 0:4 cone in the MS barrel trigger chambers. This trigger configuration implies that one v must decay in the barrel spectrometer, while the second v may decay either in the barrel or the forward spectrometer. With this trigger, it is possible to trigger on v decays at the outer radius of the hadronic calorimeter and in the MS with high efficiency. The backgrounds of punch-through jets [24] and muon bremsstrahlung are suppressed by requiring no calorimeter jets with ET 30 GeV in a cone of R ¼ 0:7 and no ID tracks with pT 5 GeV within a region of ¼ 0:2 0:2 around the RoI cluster center. These isolation criteria result in a negligible loss in the simulated signal while significantly reducing the backgrounds. As depicted in Fig. 1(a) [25], MC studies show the RoI cluster trigger is 30%–50% efficient in the region from 4 to 7 m. The v ’s that decay beyond a radius of 7 m do not leave hits in the trigger chambers located at 7 m, while the v decays that occur before r 4 m are located in the calorimeter and do not produce sufficient activity in the MS to pass the muon RoI cluster trigger. The mh0 ¼ 120 GeV and mv ¼ 40 GeV sample has a relatively lower efficiency because the v ’s have a lower boost and arrive later at the MS. As a result, the trigger signal may be associated with the incorrect bunch crossing, in which case the event is lost. The systematic uncertainty of the muon RoI cluster trigger efficiency is evaluated on data using a sample of. Trigger Efficiency. PHYSICAL REVIEW LETTERS 0.6 ATLAS Simulation. 0.5. mh=120 GeV, mπ =20 GeV v. mh=120 GeV, mπ =40 GeV. 0.4. v. mh=140 GeV, mπ =20 GeV v. mh=140 GeV, mπ =40 GeV. 0.3. v. 0.2 0.1 0 0. 1. 2. 3. 4. 5. 6. 7. 8. 9. 10 r [m]. 6. 7. 8. 9. 10 r [m]. (a) Vertex Reconstruction Efficiency. PRL 108, 251801 (2012). 0.6 ATLAS Simulation. 0.5 0.4 0.3. mh=120 GeV, m π =20 GeV. 0.2. v. mh=120 GeV, m π =40 GeV v. mh=140 GeV, m π =20 GeV. 0.1. v. mh=140 GeV, m π =40 GeV v. 0 0. 1. 2. 3. 4. 5. (b). FIG. 1 (color online). (a) Efficiency of the trigger, as a function of the radial decay position (r) of the v . (b) The vertex reconstruction efficiency for v decays in the barrel for events that pass the muon RoI cluster trigger as a function of the radial decay distance. The error bars represent the statistical uncertainty on the efficiencies.. events containing a punch-through jet. This sample of events is similar to signal events as it contains both low energy photons and charged hadrons in a localized region of the MS. These punch-through jets are selected to be in the barrel calorimeter (jj 1:4), have ET 20 GeV, have at least four tracks in the ID, each with pT 1 GeV, and have at least 20 GeV of missing transverse momentum aligned with the jet. To ensure significant activity in the MS, the jet is required to contain at least 300 MDT hits in a cone of R ¼ 0:6, centered around the jet axis [26]. The muon RoI cluster trigger algorithm was run in the vicinity of the punch-through jet for both data and MC events. The distribution of RoIs contained in the cluster for data and MC events, normalized to the number of data events, is shown in Fig. 2. The shapes of the distribution match well between data and MC events. A horizontal line fit to the ratio, as a function of NRoI 1, yields 1:14 0:09, and 14% is taken as the systematic uncertainty. The effects of uncertainties in the jet energy scale (JES) [27], in the initial state radiation (ISR) spectrum [28], and in the amount of pileup were found to be. 251801-2.

(3) Number of events. ATLAS. QCD dijet MC. 103. Data ( s=7 TeV). 102. 10. Data/MC. 1 1.5. 0. 1. 2. 3. 4. 5. 6. 7. Number of RoI’s. 1 0.5 0. 0. 1. 2. week ending 22 JUNE 2012. PHYSICAL REVIEW LETTERS. PRL 108, 251801 (2012). 3. 4. 5. 6. 7. NRoI. FIG. 2 (color online). Distribution of number of events vs number of muon RoIs from punch-through jets contained in the muon RoI cluster for both data and MC events. The error bands on the QCD dijet MC histogram represent the 1 statistical uncertainty.. negligible when varying these quantities by their uncertainties. A specialized tracking and vertex reconstruction algorithm was developed to identify v ’s that decay inside the MS. The decay of a v results in a high multiplicity of low pT particles (1 pT 5 GeV) containing 10 charged particles and 5 0 ’s clustered in a small R region of the spectrometer. The v ’s that decay before the last sampling layer of the hadronic calorimeter do not produce a significant number of tracks in the MS. Thus, detectable decay vertices must be located in the region between the outer radius of the hadronic calorimeter and the middle station of the MS. Over a wide range of acceptance in the barrel MS, the total amount of material traversed is roughly 1.3 radiation lengths [22]; therefore, as a consequence of the 5 0 ’s produced in signal events, large electromagnetic showers accompany the 10 charged particles from v decays. The resulting MS environment contains, on average, approximately 800 MDT hits, of which 75% are from the electromagnetic showers. The design of the muon chambers [22] is exploited in order to reconstruct tracks in this busy environment. The separation of the two multilayers inside a single muon chamber provides a powerful tool for track pattern recognition. This separation provides enough of a lever arm to allow, in the barrel, a momentum measurement with acceptable resolution for tracks up to approximately 10 GeV [29]. In the forward spectrometers, the muon chambers are outside the magnetic field region; therefore, it is not possible to measure the track momentum inside of a single chamber. In both cases, the tracklets used in the vertex reconstruction are formed using hits in single muon chambers. The MS vertex algorithm begins by grouping the tracklets using a simple cone algorithm with R ¼ 0:6. In the barrel, the tracklets are extrapolated through the magnetic field, and the vertex position is reconstructed as the point in. (r; z) that uses the largest number of tracklets to reconstruct a vertex with a 2 probability greater than 5%. In the forward spectrometer, the reconstructed tracklets do not have a measurement of the momentum; therefore, the vertex is found using a least squares regression that assumes the tracklets are straight lines. Vertices are required to be reconstructed using at least three tracklets, point back to the interaction point (IP) [30] and have j j 2:2. After requiring the MS vertex to be separated from ID tracks with pT 5 GeV and jets with ET 15 GeV by R ¼ 0:4 and R ¼ 0:7, respectively, the algorithm has an efficiency of 40% in signal MC events throughout the barrel region (4 r 7:5 m) and a resolution of 20 cm in z, 32 cm in r, and 50 mrad in . In the forward spectrometer, the algorithm is 40% efficient in the region 8 j z j 14 m. Figure 1(b) [25] shows the vertex reconstruction efficiency for the barrel reconstruction algorithm in MC signal events that passed the muon RoI cluster trigger. The MC description of hadrons and photons in the MS was validated on the same sample of events containing a punch-through jet used to evaluate the trigger performance. The fraction of these jets that produce a MS vertex was compared in data and QCD dijet MC events. Table I shows the fraction of punch-through jets that produce a vertex in data and MC events as a function of the number of MDT hits in a cone of R ¼ 0:6 around the jet axis. The data-toMC ratio is fit to a flat distribution that yields a ratio consistent with unity with a 15% statistical uncertainty, which is taken to be the systematic uncertainty in the vertex reconstruction efficiency. The systematic uncertainties arising from the JES, ISR spectrum, and the amount of pileup were estimated by varying these quantities by their uncertainties and calculating the change in the vertex reconstruction efficiency. The total systematic uncertainty of 16% for the efficiency of reconstructing a vertex is the sum in quadrature of the uncertainties in the efficiency of the isolation criteria due to varying the JES, ISR, and pileup (3%, 3%, and 2%, respectively) and the uncertainty in the comparison of data and MC events (15%). The final event selection requires two good MS vertices separated by R > 2. The background due to events with two jets, both of which punch through the calorimeter, is a negligible contribution to the total background due to the tight isolation criteria applied to each vertex. The background is calculated using a fully data-driven method by TABLE I. Fraction of punch-through jets that have a reconstructed vertex in the muon spectrometer for varying numbers of MDT hits for data and QCD Monte Carlo events. Number of MDT hits QCD dijet Monte Carlo 300 NMDT < 400 400 NMDT < 500 500 NMDT < 600 NMDT 600. 251801-3. 10:1 2:2% 9:2 2:8% 13:1 5:4% 16:5 4:5%. Data 9:1 0:5% 10:5 0:7% 13:0 0:9% 16:7 0:7%.

(4) 95% CL Limit on σ/ σSM. TABLE II. The excluded proper decay lengths (c) of the v , at 95% CL, for each of the signal samples, assuming 100% branching ratio for the channel h0 ! v v .. 3 95% CL Limit: m h=120 GeV, m π =20 GeV v. 95% CL Limit: m h=120 GeV, m π =40 GeV. 2.5. v. 95% CL Limit: m h=140 GeV, m π =20 GeV v. 95% CL Limit: m h=140 GeV, m π =40 GeV v. 2. mh0 ðGeVÞ. ATLAS fb ∫Ldts==71.94 TeV. -1. 1.5. 120 120 140 140. 1 0.5 0. 0. 5. 10. week ending 22 JUNE 2012. PHYSICAL REVIEW LETTERS. PRL 108, 251801 (2012). 15. 20 25 30 35 πv proper decay length [m]. FIG. 3 (color online). Observed 95% upper limits on the process h0 ! v v , vs the v proper decay length, expressed as a multiple of the SM cross section for Higgs boson production. Exclusion limits assume 100% branching ratio for the Higgs boson decaying to v ’s.. measuring the probability for a random event to contain an MS vertex (Pvertex ) and the probability of reconstructing a vertex given that the event passed the RoI cluster trigger (Preco ). Because Pvertex and Preco are measured in data, they incorporate backgrounds from cosmic showers, beam halo, and detector noise. The background is calculated as Nfake ð2 MS vertexÞ ¼ NðMS vertex; 1 trigÞPvertex þ NðMS vertex; 2 trigÞPreco : N(MS vertex, 1 trig) is the number of events with a single muon RoI cluster trigger object and an isolated MS vertex. N(MS vertex, 2 trig) is the number of events with an isolated vertex and a second RoI cluster trigger object. The first term in the equation is the expected number of background events with one vertex that randomly contain a second vertex. Preco is the probability to reconstruct a vertex given there was an RoI cluster trigger; thus, the second term in the equation is the expected number of events with two RoI clusters that have two vertices in the MS. Pvertex was measured using zero bias data [31] to be ð9:7 6:9Þ 107 , and Preco was measured using the events that pass the muon RoI cluster trigger to be ð1:11 0:01Þ 102 . The expected signal would cause, at most, a relative change in Preco of 1%. Preco was also measured using a sample of events recorded when there were no collisions. In this sample of noncollision background events, Preco was measured to be ð7:0 0:6Þ 103 . For calculating the background, the larger value of Preco (1:11 102 ) is taken since it gives a conservative estimate of the background. N(MS vertex, 1 trig) and N(MS vertex, 2 trig) are 15 543 and 1, respectively. Therefore, the background is calculated to be 0:03 0:02 events. No events in the data sample pass the selection requiring two isolated, back-to-back vertices in the muon spectrome-. mv ðGeVÞ. Excluded region. 20 40 20 40. 0:50 < c < 20:65 m 1:60 < c < 24:65 m 0:45 < c < 15:8 m 1:10 < c < 26:75 m. ter. Since no significant excess over the background prediction is found, exclusion limits for h0 BRðh0 ! v v Þ are set by rejecting the signal hypothesis at the 95% confidence level (CL) using the CLs procedure [32]. Figure 3 shows the 95% CL upper limit on h0 BRðh0 ! v v Þ=SM as a function of the v proper decay length (c) in multiples of the SM Higgs boson cross section, SM . As expected, the Higgs boson and v mass combinations with the largest boosts leading to larger c have the smallest exclusion limits. In 1:94 fb1 of pp collision data at a center-of-mass energy of 7 TeV, there is no evidence of an excess of events containing two isolated, back-to-back vertices in the ATLAS muon spectrometer. Using the model of a light Higgs boson decaying to weakly interacting, long-lived pseudoscalars, limits have been placed on the pseudoscalar proper decay length. Table II shows the broad range of v proper decay lengths that have been excluded at the 95% CL, assuming 100% branching ratio for h0 ! v v . These limits also apply to models in which the Higgs boson decays to a pair of weakly interacting scalars that, in turn, decay to heavy quark pairs. We thank CERN for the very successful operation of the LHC, as well as the support staff from our institutions without whom ATLAS could not be operated efficiently. We acknowledge the support of ANPCyT, Argentina; YerPhI, Armenia; ARC, Australia; BMWF, Austria; ANAS, Azerbaijan; SSTC, Belarus; CNPq and FAPESP, Brazil; NSERC, NRC and CFI, Canada; CERN; CONICYT, Chile; CAS, MOST and NSFC, China; COLCIENCIAS, Colombia; MSMT CR, MPO CR and VSC CR, Czech Republic; DNRF, DNSRC, and Lundbeck Foundation, Denmark; ARTEMIS, European Union; IN2P3-CNRS, CEA-DSM/IRFU, France; GNAS, Georgia; BMBF, DFG, HGF, MPG, and AvH Foundation, Germany; GSRT, Greece; ISF, MINERVA, GIF, DIP, and Benoziyo Center, Israel; INFN, Italy; MEXT and JSPS, Japan; CNRST, Morocco; FOM and NWO, Netherlands; RCN, Norway; MNiSW, Poland; GRICES and FCT, Portugal; MERYS (MECTS), Romania; MES of Russia and ROSATOM, Russian Federation; JINR; MSTD, Serbia; MSSR, Slovakia; ARRS and MVZT, Slovenia; DST/NRF, South Africa; MICINN, Spain; SRC and Wallenberg Foundation, Sweden; SER, SNSF, and Cantons of Bern and Geneva, Switzerland; NSC, Taiwan; TAEK, Turkey; STFC, the Royal Society. 251801-4.

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(6) PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. M. Antonelli,46 A. Antonov,95 J. Antos,143b F. Anulli,131a S. Aoun,82 L. Aperio Bella,4 R. Apolle,117,d G. Arabidze,87 I. Aracena,142 Y. Arai,65 A. T. H. Arce,44 J. P. Archambault,28 S. Arfaoui,147 J-F. Arguin,14 E. Arik,18a,a M. Arik,18a A. J. Armbruster,86 O. Arnaez,80 C. Arnault,114 A. Artamonov,94 G. Artoni,131a,131b D. Arutinov,20 S. Asai,154 R. Asfandiyarov,171 S. Ask,27 B. Åsman,145a,145b L. Asquith,5 K. Assamagan,24 A. Astbury,168 A. Astvatsatourov,51 B. Aubert,4 E. Auge,114 K. Augsten,126 M. Aurousseau,144a G. Avolio,162 R. Avramidou,9 D. Axen,167 C. Ay,53 G. Azuelos,92,e Y. Azuma,154 M. A. Baak,29 G. Baccaglioni,88a C. Bacci,133a,133b A. M. Bach,14 H. Bachacou,135 K. Bachas,29 G. Bachy,29 M. Backes,48 M. Backhaus,20 E. Badescu,25a P. Bagnaia,131a,131b S. Bahinipati,2 Y. Bai,32a D. C. Bailey,157 T. Bain,157 J. T. Baines,128 O. K. Baker,174 M. D. Baker,24 S. Baker,76 E. Banas,38 P. Banerjee,92 Sw. Banerjee,171 D. Banfi,29 A. Bangert,149 V. Bansal,168 H. S. Bansil,17 L. Barak,170 S. P. Baranov,93 A. Barashkou,64 A. Barbaro Galtieri,14 T. Barber,47 E. L. Barberio,85 D. Barberis,49a,49b M. Barbero,20 D. Y. Bardin,64 T. Barillari,98 M. Barisonzi,173 T. Barklow,142 N. Barlow,27 B. M. Barnett,128 R. M. Barnett,14 A. Baroncelli,133a G. Barone,48 A. J. Barr,117 F. Barreiro,79 J. Barreiro Guimarães da Costa,56 P. Barrillon,114 R. Bartoldus,142 A. E. Barton,70 V. Bartsch,148 R. L. Bates,52 L. Batkova,143a J. R. Batley,27 A. Battaglia,16 M. Battistin,29 F. Bauer,135 H. S. Bawa,142,f S. Beale,97 B. Beare,157 T. Beau,77 P. H. Beauchemin,160 R. Beccherle,49a P. Bechtle,20 H. P. Beck,16 S. Becker,97 M. Beckingham,137 K. H. Becks,173 A. J. Beddall,18c A. Beddall,18c S. Bedikian,174 V. A. Bednyakov,64 C. P. Bee,82 M. Begel,24 S. Behar Harpaz,151 P. K. Behera,62 M. Beimforde,98 C. Belanger-Champagne,84 P. J. Bell,48 W. H. Bell,48 G. Bella,152 L. Bellagamba,19a F. Bellina,29 M. Bellomo,29 A. Belloni,56 O. Beloborodova,106,g K. Belotskiy,95 O. Beltramello,29 S. Ben Ami,151 O. Benary,152 D. Benchekroun,134a C. Benchouk,82 M. Bendel,80 N. Benekos,164 Y. Benhammou,152 E. Benhar Noccioli,48 J. A. Benitez Garcia,158b D. P. Benjamin,44 M. Benoit,114 J. R. Bensinger,22 K. Benslama,129 S. Bentvelsen,104 D. Berge,29 E. Bergeaas Kuutmann,41 N. Berger,4 F. Berghaus,168 E. Berglund,104 J. Beringer,14 P. Bernat,76 R. Bernhard,47 C. Bernius,24 T. Berry,75 C. Bertella,82 A. Bertin,19a,19b F. Bertinelli,29 F. Bertolucci,121a,121b M. I. Besana,88a,88b N. Besson,135 S. Bethke,98 W. Bhimji,45 R. M. Bianchi,29 M. Bianco,71a,71b O. Biebel,97 S. P. Bieniek,76 K. Bierwagen,53 J. Biesiada,14 M. Biglietti,133a H. Bilokon,46 M. Bindi,19a,19b S. Binet,114 A. Bingul,18c C. Bini,131a,131b C. Biscarat,176 U. Bitenc,47 K. M. Black,21 R. E. Blair,5 J.-B. Blanchard,135 G. Blanchot,29 T. Blazek,143a C. Blocker,22 J. Blocki,38 A. Blondel,48 W. Blum,80 U. Blumenschein,53 G. J. Bobbink,104 V. B. Bobrovnikov,106 S. S. Bocchetta,78 A. Bocci,44 C. R. Boddy,117 M. Boehler,41 J. Boek,173 N. Boelaert,35 S. Böser,76 J. A. Bogaerts,29 A. Bogdanchikov,106 A. Bogouch,89,a C. Bohm,145a V. Boisvert,75 T. Bold,37 V. Boldea,25a N. M. Bolnet,135 M. Bona,74 V. G. Bondarenko,95 M. Bondioli,162 M. Boonekamp,135 G. Boorman,75 C. N. Booth,138 S. Bordoni,77 C. Borer,16 A. Borisov,127 G. Borissov,70 I. Borjanovic,12a S. Borroni,86 K. Bos,104 D. Boscherini,19a M. Bosman,11 H. Boterenbrood,104 D. Botterill,128 J. Bouchami,92 J. Boudreau,122 E. V. Bouhova-Thacker,70 D. Boumediene,33 C. Bourdarios,114 N. Bousson,82 A. Boveia,30 J. Boyd,29 I. R. Boyko,64 N. I. Bozhko,127 I. Bozovic-Jelisavcic,12b J. Bracinik,17 A. Braem,29 P. Branchini,133a G. W. Brandenburg,56 A. Brandt,7 G. Brandt,117 O. Brandt,53 U. Bratzler,155 B. Brau,83 J. E. Brau,113 H. M. Braun,173 B. Brelier,157 J. Bremer,29 R. Brenner,165 S. Bressler,170 D. Breton,114 D. Britton,52 F. M. Brochu,27 I. Brock,20 R. Brock,87 T. J. Brodbeck,70 E. Brodet,152 F. Broggi,88a C. Bromberg,87 J. Bronner,98 G. Brooijmans,34 W. K. Brooks,31b G. Brown,81 H. Brown,7 P. A. Bruckman de Renstrom,38 D. Bruncko,143b R. Bruneliere,47 S. Brunet,60 A. Bruni,19a G. Bruni,19a M. Bruschi,19a T. Buanes,13 Q. Buat,54 F. Bucci,48 J. Buchanan,117 N. J. Buchanan,2 P. Buchholz,140 R. M. Buckingham,117 A. G. Buckley,45 S. I. Buda,25a I. A. Budagov,64 B. Budick,107 V. Büscher,80 L. Bugge,116 O. Bulekov,95 M. Bunse,42 T. Buran,116 H. Burckhart,29 S. Burdin,72 T. Burgess,13 S. Burke,128 E. Busato,33 P. Bussey,52 C. P. Buszello,165 F. Butin,29 B. Butler,142 J. M. Butler,21 C. M. Buttar,52 J. M. Butterworth,76 W. Buttinger,27 S. Cabrera Urbán,166 D. Caforio,19a,19b O. Cakir,3a P. Calafiura,14 G. Calderini,77 P. Calfayan,97 R. Calkins,105 L. P. Caloba,23a R. Caloi,131a,131b D. Calvet,33 S. Calvet,33 R. Camacho Toro,33 P. Camarri,132a,132b M. Cambiaghi,118a,118b D. Cameron,116 L. M. Caminada,14 S. Campana,29 M. Campanelli,76 V. Canale,101a,101b F. Canelli,30,h A. Canepa,158a J. Cantero,79 L. Capasso,101a,101b M. D. M. Capeans Garrido,29 I. Caprini,25a M. Caprini,25a D. Capriotti,98 M. Capua,36a,36b R. Caputo,80 C. Caramarcu,24 R. Cardarelli,132a T. Carli,29 G. Carlino,101a L. Carminati,88a,88b B. Caron,84 S. Caron,103 G. D. Carrillo Montoya,171 A. A. Carter,74 J. R. Carter,27 J. Carvalho,123a,i D. Casadei,107 M. P. Casado,11 M. Cascella,121a,121b C. Caso,49a,49b,a A. M. Castaneda Hernandez,171 E. Castaneda-Miranda,171 V. Castillo Gimenez,166 N. F. Castro,123a G. Cataldi,71a F. Cataneo,29 A. Catinaccio,29 J. R. Catmore,29 A. Cattai,29 G. Cattani,132a,132b S. Caughron,87 D. Cauz,163a,163c P. Cavalleri,77 D. Cavalli,88a M. Cavalli-Sforza,11 V. Cavasinni,121a,121b F. Ceradini,133a,133b A. S. Cerqueira,23b A. Cerri,29 L. Cerrito,74 F. Cerutti,46 S. A. Cetin,18b 251801-6.

(7) PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. F. Cevenini,101a,101b A. Chafaq,134a D. Chakraborty,105 K. Chan,2 B. Chapleau,84 J. D. Chapman,27 J. W. Chapman,86 E. Chareyre,77 D. G. Charlton,17 V. Chavda,81 C. A. Chavez Barajas,29 S. Cheatham,84 S. Chekanov,5 S. V. Chekulaev,158a G. A. Chelkov,64 M. A. Chelstowska,103 C. Chen,63 H. Chen,24 S. Chen,32c T. Chen,32c X. Chen,171 S. Cheng,32a A. Cheplakov,64 V. F. Chepurnov,64 R. Cherkaoui El Moursli,134e V. Chernyatin,24 E. Cheu,6 S. L. Cheung,157 L. Chevalier,135 G. Chiefari,101a,101b L. Chikovani,50a J. T. Childers,29 A. Chilingarov,70 G. Chiodini,71a M. V. Chizhov,64 G. Choudalakis,30 S. Chouridou,136 I. A. Christidi,76 A. Christov,47 D. Chromek-Burckhart,29 M. L. Chu,150 J. Chudoba,124 G. Ciapetti,131a,131b K. Ciba,37 A. K. Ciftci,3a R. Ciftci,3a D. Cinca,33 V. Cindro,73 M. D. Ciobotaru,162 C. Ciocca,19a A. Ciocio,14 M. Cirilli,86 M. Citterio,88a M. Ciubancan,25a A. Clark,48 P. J. Clark,45 W. Cleland,122 J. C. Clemens,82 B. Clement,54 C. Clement,145a,145b R. W. Clifft,128 Y. Coadou,82 M. Cobal,163a,163c A. Coccaro,171 J. Cochran,63 P. Coe,117 J. G. Cogan,142 J. Coggeshall,164 E. Cogneras,176 J. Colas,4 A. P. Colijn,104 N. J. Collins,17 C. Collins-Tooth,52 J. Collot,54 G. Colon,83 P. Conde Muiño,123a E. Coniavitis,117 M. C. Conidi,11 M. Consonni,103 V. Consorti,47 S. Constantinescu,25a C. Conta,118a,118b F. Conventi,101a,j J. Cook,29 M. Cooke,14 B. D. Cooper,76 A. M. Cooper-Sarkar,117 K. Copic,14 T. Cornelissen,173 M. Corradi,19a F. Corriveau,84,k A. Cortes-Gonzalez,164 G. Cortiana,98 G. Costa,88a M. J. Costa,166 D. Costanzo,138 T. Costin,30 D. Côté,29 R. Coura Torres,23a L. Courneyea,168 G. Cowan,75 C. Cowden,27 B. E. Cox,81 K. Cranmer,107 F. Crescioli,121a,121b M. Cristinziani,20 G. Crosetti,36a,36b R. Crupi,71a,71b S. Crépé-Renaudin,54 C.-M. Cuciuc,25a C. Cuenca Almenar,174 T. Cuhadar Donszelmann,138 M. Curatolo,46 C. J. Curtis,17 C. Cuthbert,149 P. Cwetanski,60 H. Czirr,140 P. Czodrowski,43 Z. Czyczula,174 S. D’Auria,52 M. D’Onofrio,72 A. D’Orazio,131a,131b P. V. M. Da Silva,23a C. Da Via,81 W. Dabrowski,37 T. Dai,86 C. Dallapiccola,83 M. Dam,35 M. Dameri,49a,49b D. S. Damiani,136 H. O. Danielsson,29 D. Dannheim,98 V. Dao,48 G. Darbo,49a G. L. Darlea,25b C. Daum,104 W. Davey,20 T. Davidek,125 N. Davidson,85 R. Davidson,70 E. Davies,117,d M. Davies,92 A. R. Davison,76 Y. Davygora,57a E. Dawe,141 I. Dawson,138,a J. W. Dawson,5,a R. K. Daya-Ishmukhametova,22 K. De,7 R. de Asmundis,101a S. De Castro,19a,19b P. E. De Castro Faria Salgado,24 S. De Cecco,77 J. de Graat,97 N. De Groot,103 P. de Jong,104 C. De La Taille,114 H. De la Torre,79 B. De Lotto,163a,163c L. de Mora,70 L. De Nooij,104 D. De Pedis,131a A. De Salvo,131a U. De Sanctis,163a,163c A. De Santo,148 J. B. De Vivie De Regie,114 S. Dean,76 W. J. Dearnaley,70 R. Debbe,24 C. Debenedetti,45 D. V. Dedovich,64 J. Degenhardt,119 M. Dehchar,117 C. Del Papa,163a,163c J. Del Peso,79 T. Del Prete,121a,121b T. Delemontex,54 M. Deliyergiyev,73 A. Dell’Acqua,29 L. Dell’Asta,21 M. Della Pietra,101a,j D. della Volpe,101a,101b M. Delmastro,4 N. Delruelle,29 P. A. Delsart,54 C. Deluca,147 S. Demers,174 M. Demichev,64 B. Demirkoz,11,l J. Deng,162 S. P. Denisov,127 D. Derendarz,38 J. E. Derkaoui,134d F. Derue,77 P. Dervan,72 K. Desch,20 E. Devetak,147 P. O. Deviveiros,104 A. Dewhurst,128 B. DeWilde,147 S. Dhaliwal,157 R. Dhullipudi,24,m A. Di Ciaccio,132a,132b L. Di Ciaccio,4 A. Di Girolamo,29 B. Di Girolamo,29 S. Di Luise,133a,133b A. Di Mattia,171 B. Di Micco,29 R. Di Nardo,46 A. Di Simone,132a,132b R. Di Sipio,19a,19b M. A. Diaz,31a F. Diblen,18c E. B. Diehl,86 J. Dietrich,41 T. A. Dietzsch,57a S. Diglio,85 K. Dindar Yagci,39 J. Dingfelder,20 C. Dionisi,131a,131b P. Dita,25a S. Dita,25a F. Dittus,29 F. Djama,82 T. Djobava,50b M. A. B. do Vale,23c A. Do Valle Wemans,123a T. K. O. Doan,4 M. Dobbs,84 R. Dobinson,29,a D. Dobos,29 E. Dobson,29,n J. Dodd,34 C. Doglioni,48 T. Doherty,52 Y. Doi,65,a J. Dolejsi,125 I. Dolenc,73 Z. Dolezal,125 B. A. Dolgoshein,95,a T. Dohmae,154 M. Donadelli,23d M. Donega,119 J. Donini,33 J. Dopke,29 A. Doria,101a A. Dos Anjos,171 M. Dosil,11 A. Dotti,121a,121b M. T. Dova,69 J. D. Dowell,17 A. D. Doxiadis,104 A. T. Doyle,52 Z. Drasal,125 J. Drees,173 N. Dressnandt,119 H. Drevermann,29 C. Driouichi,35 M. Dris,9 J. Dubbert,98 S. Dube,14 E. Duchovni,170 G. Duckeck,97 A. Dudarev,29 F. Dudziak,63 M. Dührssen,29 I. P. Duerdoth,81 L. Duflot,114 M-A. Dufour,84 M. Dunford,29 H. Duran Yildiz,3a R. Duxfield,138 M. Dwuznik,37 F. Dydak,29 M. Düren,51 W. L. Ebenstein,44 J. Ebke,97 S. Eckweiler,80 K. Edmonds,80 C. A. Edwards,75 N. C. Edwards,52 W. Ehrenfeld,41 T. Ehrich,98 T. Eifert,142 G. Eigen,13 K. Einsweiler,14 E. Eisenhandler,74 T. Ekelof,165 M. El Kacimi,134c M. Ellert,165 S. Elles,4 F. Ellinghaus,80 K. Ellis,74 N. Ellis,29 J. Elmsheuser,97 M. Elsing,29 D. Emeliyanov,128 R. Engelmann,147 A. Engl,97 B. Epp,61 A. Eppig,86 J. Erdmann,53 A. Ereditato,16 D. Eriksson,145a J. Ernst,1 M. Ernst,24 J. Ernwein,135 D. Errede,164 S. Errede,164 E. Ertel,80 M. Escalier,114 C. Escobar,122 X. Espinal Curull,11 B. Esposito,46 F. Etienne,82 A. I. Etienvre,135 E. Etzion,152 D. Evangelakou,53 H. Evans,60 L. Fabbri,19a,19b C. Fabre,29 R. M. Fakhrutdinov,127 S. Falciano,131a Y. Fang,171 M. Fanti,88a,88b A. Farbin,7 A. Farilla,133a J. Farley,147 T. Farooque,157 S. M. Farrington,117 P. Farthouat,29 P. Fassnacht,29 D. Fassouliotis,8 B. Fatholahzadeh,157 A. Favareto,88a,88b L. Fayard,114 S. Fazio,36a,36b R. Febbraro,33 P. Federic,143a O. L. Fedin,120 W. Fedorko,87 M. Fehling-Kaschek,47 L. Feligioni,82 D. Fellmann,5 C. Feng,32d E. J. Feng,30 A. B. Fenyuk,127 J. Ferencei,143b J. Ferland,92 W. Fernando,108 251801-7.

(8) PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. S. Ferrag,52 J. Ferrando,52 V. Ferrara,41 A. Ferrari,165 P. Ferrari,104 R. Ferrari,118a A. Ferrer,166 M. L. Ferrer,46 D. Ferrere,48 C. Ferretti,86 A. Ferretto Parodi,49a,49b M. Fiascaris,30 F. Fiedler,80 A. Filipčič,73 A. Filippas,9 F. Filthaut,103 M. Fincke-Keeler,168 M. C. N. Fiolhais,123a,i L. Fiorini,166 A. Firan,39 G. Fischer,41 P. Fischer,20 M. J. Fisher,108 M. Flechl,47 I. Fleck,140 J. Fleckner,80 P. Fleischmann,172 S. Fleischmann,173 T. Flick,173 L. R. Flores Castillo,171 M. J. Flowerdew,98 M. Fokitis,9 T. Fonseca Martin,16 D. A. Forbush,137 A. Formica,135 A. Forti,81 D. Fortin,158a J. M. Foster,81 D. Fournier,114 A. Foussat,29 A. J. Fowler,44 K. Fowler,136 H. Fox,70 P. Francavilla,11 S. Franchino,118a,118b D. Francis,29 T. Frank,170 M. Franklin,56 S. Franz,29 M. Fraternali,118a,118b S. Fratina,119 S. T. French,27 F. Friedrich,43 R. Froeschl,29 D. Froidevaux,29 J. A. Frost,27 C. Fukunaga,155 E. Fullana Torregrosa,29 J. Fuster,166 C. Gabaldon,29 O. Gabizon,170 T. Gadfort,24 S. Gadomski,48 G. Gagliardi,49a,49b P. Gagnon,60 C. Galea,97 E. J. Gallas,117 V. Gallo,16 B. J. Gallop,128 P. Gallus,124 K. K. Gan,108 Y. S. Gao,142,f V. A. Gapienko,127 A. Gaponenko,14 F. Garberson,174 M. Garcia-Sciveres,14 C. Garcı́a,166 J. E. Garcı́a Navarro,166 R. W. Gardner,30 N. Garelli,29 H. Garitaonandia,104 V. Garonne,29 J. Garvey,17 C. Gatti,46 G. Gaudio,118a O. Gaumer,48 B. Gaur,140 L. Gauthier,135 I. L. Gavrilenko,93 C. Gay,167 G. Gaycken,20 J-C. Gayde,29 E. N. Gazis,9 P. Ge,32d C. N. P. Gee,128 D. A. A. Geerts,104 Ch. Geich-Gimbel,20 K. Gellerstedt,145a,145b C. Gemme,49a A. Gemmell,52 M. H. Genest,54 S. Gentile,131a,131b M. George,53 S. George,75 P. Gerlach,173 A. Gershon,152 C. Geweniger,57a H. Ghazlane,134b N. Ghodbane,33 B. Giacobbe,19a S. Giagu,131a,131b V. Giakoumopoulou,8 V. Giangiobbe,11 F. Gianotti,29 B. Gibbard,24 A. Gibson,157 S. M. Gibson,29 L. M. Gilbert,117 V. Gilewsky,90 D. Gillberg,28 A. R. Gillman,128 D. M. Gingrich,2,e J. Ginzburg,152 N. Giokaris,8 M. P. Giordani,163c R. Giordano,101a,101b F. M. Giorgi,15 P. Giovannini,98 P. F. Giraud,135 D. Giugni,88a M. Giunta,92 P. Giusti,19a B. K. Gjelsten,116 L. K. Gladilin,96 C. Glasman,79 J. Glatzer,47 A. Glazov,41 K. W. Glitza,173 G. L. Glonti,64 J. R. Goddard,74 J. Godfrey,141 J. Godlewski,29 M. Goebel,41 T. Göpfert,43 C. Goeringer,80 C. Gössling,42 T. Göttfert,98 S. Goldfarb,86 T. Golling,174 S. N. Golovnia,127 A. Gomes,123a,c L. S. Gomez Fajardo,41 R. Gonçalo,75 J. Goncalves Pinto Firmino Da Costa,41 L. Gonella,20 A. Gonidec,29 S. Gonzalez,171 S. González de la Hoz,166 G. Gonzalez Parra,11 M. L. Gonzalez Silva,26 S. Gonzalez-Sevilla,48 J. J. Goodson,147 L. Goossens,29 P. A. Gorbounov,94 H. A. Gordon,24 I. Gorelov,102 G. Gorfine,173 B. Gorini,29 E. Gorini,71a,71b A. Gorišek,73 E. Gornicki,38 S. A. Gorokhov,127 V. N. Goryachev,127 B. Gosdzik,41 M. Gosselink,104 M. I. Gostkin,64 I. Gough Eschrich,162 M. Gouighri,134a D. Goujdami,134c M. P. Goulette,48 A. G. Goussiou,137 C. Goy,4 S. Gozpinar,22 I. Grabowska-Bold,37 P. Grafström,29 K-J. Grahn,41 F. Grancagnolo,71a S. Grancagnolo,15 V. Grassi,147 V. Gratchev,120 N. Grau,34 H. M. Gray,29 J. A. Gray,147 E. Graziani,133a O. G. Grebenyuk,120 T. Greenshaw,72 Z. D. Greenwood,24,m K. Gregersen,35 I. M. Gregor,41 P. Grenier,142 J. Griffiths,137 N. Grigalashvili,64 A. A. Grillo,136 S. Grinstein,11 Y. V. Grishkevich,96 J.-F. Grivaz,114 M. Groh,98 E. Gross,170 J. Grosse-Knetter,53 J. Groth-Jensen,170 K. Grybel,140 V. J. Guarino,5 D. Guest,174 C. Guicheney,33 A. Guida,71a,71b S. Guindon,53 H. Guler,84,o J. Gunther,124 B. Guo,157 J. Guo,34 A. Gupta,30 Y. Gusakov,64 V. N. Gushchin,127 A. Gutierrez,92 P. Gutierrez,110 N. Guttman,152 O. Gutzwiller,171 C. Guyot,135 C. Gwenlan,117 C. B. Gwilliam,72 A. Haas,142 S. Haas,29 C. Haber,14 H. K. Hadavand,39 D. R. Hadley,17 P. Haefner,98 F. Hahn,29 S. Haider,29 Z. Hajduk,38 H. Hakobyan,175 D. Hall,117 J. Haller,53 K. Hamacher,173 P. Hamal,112 M. Hamer,53 A. Hamilton,144b,p S. Hamilton,160 H. Han,32a L. Han,32b K. Hanagaki,115 K. Hanawa,159 M. Hance,14 C. Handel,80 P. Hanke,57a J. R. Hansen,35 J. B. Hansen,35 J. D. Hansen,35 P. H. Hansen,35 P. Hansson,142 K. Hara,159 G. A. Hare,136 T. Harenberg,173 S. Harkusha,89 D. Harper,86 R. D. Harrington,45 O. M. Harris,137 K. Harrison,17 J. Hartert,47 F. Hartjes,104 T. Haruyama,65 A. Harvey,55 S. Hasegawa,100 Y. Hasegawa,139 S. Hassani,135 M. Hatch,29 D. Hauff,98 S. Haug,16 M. Hauschild,29 R. Hauser,87 M. Havranek,20 B. M. Hawes,117 C. M. Hawkes,17 R. J. Hawkings,29 A. D. Hawkins,78 D. Hawkins,162 T. Hayakawa,66 T. Hayashi,159 D. Hayden,75 H. S. Hayward,72 S. J. Haywood,128 E. Hazen,21 M. He,32d S. J. Head,17 V. Hedberg,78 L. Heelan,7 S. Heim,87 B. Heinemann,14 S. Heisterkamp,35 L. Helary,4 C. Heller,97 M. Heller,29 S. Hellman,145a,145b D. Hellmich,20 C. Helsens,11 R. C. W. Henderson,70 M. Henke,57a A. Henrichs,53 A. M. Henriques Correia,29 S. Henrot-Versille,114 F. Henry-Couannier,82 C. Hensel,53 T. Henß,173 C. M. Hernandez,7 Y. Hernández Jiménez,166 R. Herrberg,15 A. D. Hershenhorn,151 G. Herten,47 R. Hertenberger,97 L. Hervas,29 N. P. Hessey,104 E. Higón-Rodriguez,166 D. Hill,5,a J. C. Hill,27 N. Hill,5 K. H. Hiller,41 S. Hillert,20 S. J. Hillier,17 I. Hinchliffe,14 E. Hines,119 M. Hirose,115 F. Hirsch,42 D. Hirschbuehl,173 J. Hobbs,147 N. Hod,152 M. C. Hodgkinson,138 P. Hodgson,138 A. Hoecker,29 M. R. Hoeferkamp,102 J. Hoffman,39 D. Hoffmann,82 M. Hohlfeld,80 M. Holder,140 S. O. Holmgren,145a T. Holy,126 J. L. Holzbauer,87 Y. Homma,66 T. M. Hong,119 L. Hooft van Huysduynen,107 T. Horazdovsky,126 C. Horn,142 S. Horner,47 J-Y. Hostachy,54 S. Hou,150 251801-8.

(9) PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. M. A. Houlden,72 A. Hoummada,134a J. Howarth,81 D. F. Howell,117 I. Hristova,15 J. Hrivnac,114 I. Hruska,124 T. Hryn’ova,4 P. J. Hsu,80 S.-C. Hsu,14 G. S. Huang,110 Z. Hubacek,126 F. Hubaut,82 F. Huegging,20 A. Huettmann,41 T. B. Huffman,117 E. W. Hughes,34 G. Hughes,70 R. E. Hughes-Jones,81 M. Huhtinen,29 P. Hurst,56 M. Hurwitz,14 U. Husemann,41 N. Huseynov,64,q J. Huston,87 J. Huth,56 G. Iacobucci,48 G. Iakovidis,9 M. Ibbotson,81 I. Ibragimov,140 R. Ichimiya,66 L. Iconomidou-Fayard,114 J. Idarraga,114 P. Iengo,101a O. Igonkina,104 Y. Ikegami,65 M. Ikeno,65 Y. Ilchenko,39 D. Iliadis,153 N. Ilic,157 D. Imbault,77 M. Imori,154 T. Ince,20 J. Inigo-Golfin,29 P. Ioannou,8 M. Iodice,133a V. Ippolito,131a,131b A. Irles Quiles,166 C. Isaksson,165 A. Ishikawa,66 M. Ishino,67 R. Ishmukhametov,39 C. Issever,117 S. Istin,18a A. V. Ivashin,127 W. Iwanski,38 H. Iwasaki,65 J. M. Izen,40 V. Izzo,101a B. Jackson,119 J. N. Jackson,72 P. Jackson,142 M. R. Jaekel,29 V. Jain,60 K. Jakobs,47 S. Jakobsen,35 J. Jakubek,126 D. K. Jana,110 E. Jankowski,157 E. Jansen,76 H. Jansen,29 A. Jantsch,98 M. Janus,20 G. Jarlskog,78 L. Jeanty,56 K. Jelen,37 I. Jen-La Plante,30 P. Jenni,29 A. Jeremie,4 P. Jež,35 S. Jézéquel,4 M. K. Jha,19a H. Ji,171 W. Ji,80 J. Jia,147 Y. Jiang,32b M. Jimenez Belenguer,41 G. Jin,32b S. Jin,32a O. Jinnouchi,156 M. D. Joergensen,35 D. Joffe,39 L. G. Johansen,13 M. Johansen,145a,145b K. E. Johansson,145a P. Johansson,138 S. Johnert,41 K. A. Johns,6 K. Jon-And,145a,145b G. Jones,81 R. W. L. Jones,70 T. W. Jones,76 T. J. Jones,72 O. Jonsson,29 C. Joram,29 P. M. Jorge,123a J. Joseph,14 T. Jovin,12b X. Ju,171 C. A. Jung,42 R. M. Jungst,29 V. Juranek,124 P. Jussel,61 A. Juste Rozas,11 V. V. Kabachenko,127 S. Kabana,16 M. Kaci,166 A. Kaczmarska,38 P. Kadlecik,35 M. Kado,114 H. Kagan,108 M. Kagan,56 S. Kaiser,98 E. Kajomovitz,151 S. Kalinin,173 L. V. Kalinovskaya,64 S. Kama,39 N. Kanaya,154 M. Kaneda,29 S. Kaneti,27 T. Kanno,156 V. A. Kantserov,95 J. Kanzaki,65 B. Kaplan,174 A. Kapliy,30 J. Kaplon,29 D. Kar,43 M. Karagounis,20 M. Karagoz,117 M. Karnevskiy,41 K. Karr,5 V. Kartvelishvili,70 A. N. Karyukhin,127 L. Kashif,171 G. Kasieczka,57b R. D. Kass,108 A. Kastanas,13 M. Kataoka,4 Y. Kataoka,154 E. Katsoufis,9 J. Katzy,41 V. Kaushik,6 K. Kawagoe,66 T. Kawamoto,154 G. Kawamura,80 M. S. Kayl,104 V. A. Kazanin,106 M. Y. Kazarinov,64 R. Keeler,168 R. Kehoe,39 M. Keil,53 G. D. Kekelidze,64 J. Kennedy,97 C. J. Kenney,142 M. Kenyon,52 O. Kepka,124 N. Kerschen,29 B. P. Kerševan,73 S. Kersten,173 K. Kessoku,154 J. Keung,157 F. Khalil-zada,10 H. Khandanyan,164 A. Khanov,111 D. Kharchenko,64 A. Khodinov,95 A. G. Kholodenko,127 A. Khomich,57a T. J. Khoo,27 G. Khoriauli,20 A. Khoroshilov,173 N. Khovanskiy,64 V. Khovanskiy,94 E. Khramov,64 J. Khubua,50b H. Kim,145a,145b M. S. Kim,2 P. C. Kim,142 S. H. Kim,159 N. Kimura,169 O. Kind,15 B. T. King,72 M. King,66 R. S. B. King,117 J. Kirk,128 L. E. Kirsch,22 A. E. Kiryunin,98 T. Kishimoto,66 D. Kisielewska,37 T. Kittelmann,122 A. M. Kiver,127 E. Kladiva,143b J. Klaiber-Lodewigs,42 M. Klein,72 U. Klein,72 K. Kleinknecht,80 M. Klemetti,84 A. Klier,170 P. Klimek,145a,145b A. Klimentov,24 R. Klingenberg,42 E. B. Klinkby,35 T. Klioutchnikova,29 P. F. Klok,103 S. Klous,104 E.-E. Kluge,57a T. Kluge,72 P. Kluit,104 S. Kluth,98 N. S. Knecht,157 E. Kneringer,61 J. Knobloch,29 E. B. F. G. Knoops,82 A. Knue,53 B. R. Ko,44 T. Kobayashi,154 M. Kobel,43 M. Kocian,142 P. Kodys,125 K. Köneke,29 A. C. König,103 S. Koenig,80 L. Köpke,80 F. Koetsveld,103 P. Koevesarki,20 T. Koffas,28 E. Koffeman,104 L. A. Kogan,117 F. Kohn,53 Z. Kohout,126 T. Kohriki,65 T. Koi,142 T. Kokott,20 G. M. Kolachev,106 H. Kolanoski,15 V. Kolesnikov,64 I. Koletsou,88a J. Koll,87 D. Kollar,29 M. Kollefrath,47 S. D. Kolya,81 A. A. Komar,93 Y. Komori,154 T. Kondo,65 T. Kono,41,r A. I. Kononov,47 R. Konoplich,107,s N. Konstantinidis,76 A. Kootz,173 S. Koperny,37 K. Korcyl,38 K. Kordas,153 V. Koreshev,127 A. Korn,117 A. Korol,106 I. Korolkov,11 E. V. Korolkova,138 V. A. Korotkov,127 O. Kortner,98 S. Kortner,98 V. V. Kostyukhin,20 M. J. Kotamäki,29 S. Kotov,98 V. M. Kotov,64 A. Kotwal,44 C. Kourkoumelis,8 V. Kouskoura,153 A. Koutsman,158a R. Kowalewski,168 T. Z. Kowalski,37 W. Kozanecki,135 A. S. Kozhin,127 V. Kral,126 V. A. Kramarenko,96 G. Kramberger,73 M. W. Krasny,77 A. Krasznahorkay,107 J. Kraus,87 J. K. Kraus,20 A. Kreisel,152 F. Krejci,126 J. Kretzschmar,72 N. Krieger,53 P. Krieger,157 K. Kroeninger,53 H. Kroha,98 J. Kroll,119 J. Kroseberg,20 J. Krstic,12a U. Kruchonak,64 H. Krüger,20 T. Kruker,16 N. Krumnack,63 Z. V. Krumshteyn,64 A. Kruth,20 T. Kubota,85 S. Kuehn,47 A. Kugel,57c T. Kuhl,41 D. Kuhn,61 V. Kukhtin,64 Y. Kulchitsky,89 S. Kuleshov,31b C. Kummer,97 M. Kuna,77 N. Kundu,117 J. Kunkle,119 A. Kupco,124 H. Kurashige,66 M. Kurata,159 Y. A. Kurochkin,89 V. Kus,124 E. S. Kuwertz,146 M. Kuze,156 J. Kvita,141 R. Kwee,15 A. La Rosa,48 L. La Rotonda,36a,36b L. Labarga,79 J. Labbe,4 S. Lablak,134a C. Lacasta,166 F. Lacava,131a,131b H. Lacker,15 D. Lacour,77 V. R. Lacuesta,166 E. Ladygin,64 R. Lafaye,4 B. Laforge,77 T. Lagouri,79 S. Lai,47 E. Laisne,54 M. Lamanna,29 C. L. Lampen,6 W. Lampl,6 E. Lancon,135 U. Landgraf,47 M. P. J. Landon,74 H. Landsman,151 J. L. Lane,81 C. Lange,41 A. J. Lankford,162 F. Lanni,24 K. Lantzsch,173 S. Laplace,77 C. Lapoire,20 J. F. Laporte,135 T. Lari,88a A. V. Larionov,127 A. Larner,117 C. Lasseur,29 M. Lassnig,29 P. Laurelli,46 W. Lavrijsen,14 P. Laycock,72 A. B. Lazarev,64 O. Le Dortz,77 E. Le Guirriec,82 C. Le Maner,157 E. Le Menedeu,9 C. Lebel,92 T. LeCompte,5 F. Ledroit-Guillon,54 H. Lee,104 251801-9.

(10) PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. J. S. H. Lee,115 S. C. Lee,150 L. Lee,174 M. Lefebvre,168 M. Legendre,135 A. Leger,48 B. C. LeGeyt,119 F. Legger,97 C. Leggett,14 M. Lehmacher,20 G. Lehmann Miotto,29 X. Lei,6 M. A. L. Leite,23d R. Leitner,125 D. Lellouch,170 M. Leltchouk,34 B. Lemmer,53 V. Lendermann,57a K. J. C. Leney,144b T. Lenz,104 G. Lenzen,173 B. Lenzi,29 K. Leonhardt,43 S. Leontsinis,9 C. Leroy,92 J-R. Lessard,168 J. Lesser,145a C. G. Lester,27 A. Leung Fook Cheong,171 J. Levêque,4 D. Levin,86 L. J. Levinson,170 M. S. Levitski,127 A. Lewis,117 G. H. Lewis,107 A. M. Leyko,20 M. Leyton,15 B. Li,82 H. Li,171,t S. Li,32b,u X. Li,86 Z. Liang,117,v H. Liao,33 B. Liberti,132a P. Lichard,29 M. Lichtnecker,97 K. Lie,164 W. Liebig,13 R. Lifshitz,151 C. Limbach,20 A. Limosani,85 M. Limper,62 S. C. Lin,150,w F. Linde,104 J. T. Linnemann,87 E. Lipeles,119 L. Lipinsky,124 A. Lipniacka,13 T. M. Liss,164 D. Lissauer,24 A. Lister,48 A. M. Litke,136 C. Liu,28 D. Liu,150 H. Liu,86 J. B. Liu,86 M. Liu,32b S. Liu,2 Y. Liu,32b M. Livan,118a,118b S. S. A. Livermore,117 A. Lleres,54 J. Llorente Merino,79 S. L. Lloyd,74 E. Lobodzinska,41 P. Loch,6 W. S. Lockman,136 T. Loddenkoetter,20 F. K. Loebinger,81 A. Loginov,174 C. W. Loh,167 T. Lohse,15 K. Lohwasser,47 M. Lokajicek,124 J. Loken,117 V. P. Lombardo,4 R. E. Long,70 L. Lopes,123a,c D. Lopez Mateos,56 J. Lorenz,97 M. Losada,161 P. Loscutoff,14 F. Lo Sterzo,131a,131b M. J. Losty,158a X. Lou,40 A. Lounis,114 K. F. Loureiro,161 J. Love,21 P. A. Love,70 A. J. Lowe,142,f F. Lu,32a H. J. Lubatti,137 C. Luci,131a,131b A. Lucotte,54 A. Ludwig,43 D. Ludwig,41 I. Ludwig,47 J. Ludwig,47 F. Luehring,60 G. Luijckx,104 D. Lumb,47 L. Luminari,131a E. Lund,116 B. Lund-Jensen,146 B. Lundberg,78 J. Lundberg,145a,145b J. Lundquist,35 M. Lungwitz,80 G. Lutz,98 D. Lynn,24 J. Lys,14 E. Lytken,78 H. Ma,24 L. L. Ma,171 J. A. Macana Goia,92 G. Maccarrone,46 A. Macchiolo,98 B. Maček,73 J. Machado Miguens,123a R. Mackeprang,35 R. J. Madaras,14 W. F. Mader,43 R. Maenner,57c T. Maeno,24 P. Mättig,173 S. Mättig,41 L. Magnoni,29 E. Magradze,53 Y. Mahalalel,152 K. Mahboubi,47 G. Mahout,17 C. Maiani,131a,131b C. Maidantchik,23a A. Maio,123a,c S. Majewski,24 Y. Makida,65 N. Makovec,114 P. Mal,135 B. Malaescu,29 Pa. Malecki,38 P. Malecki,38 V. P. Maleev,120 F. Malek,54 U. Mallik,62 D. Malon,5 C. Malone,142 S. Maltezos,9 V. Malyshev,106 S. Malyukov,29 R. Mameghani,97 J. Mamuzic,12b A. Manabe,65 L. Mandelli,88a I. Mandić,73 R. Mandrysch,15 J. Maneira,123a P. S. Mangeard,87 L. Manhaes de Andrade Filho,23a I. D. Manjavidze,64 A. Mann,53 P. M. Manning,136 A. Manousakis-Katsikakis,8 B. Mansoulie,135 A. Manz,98 A. Mapelli,29 L. Mapelli,29 L. March,79 J. F. Marchand,28 F. Marchese,132a,132b G. Marchiori,77 M. Marcisovsky,124 A. Marin,21,a C. P. Marino,168,a F. Marroquim,23a R. Marshall,81 Z. Marshall,29 F. K. Martens,157 S. Marti-Garcia,166 A. J. Martin,174 B. Martin,29 B. Martin,87 F. F. Martin,119 J. P. Martin,92 Ph. Martin,54 T. A. Martin,17 V. J. Martin,45 B. Martin dit Latour,48 S. Martin-Haugh,148 M. Martinez,11 V. Martinez Outschoorn,56 A. C. Martyniuk,168 M. Marx,81 F. Marzano,131a A. Marzin,110 L. Masetti,80 T. Mashimo,154 R. Mashinistov,93 J. Masik,81 A. L. Maslennikov,106 I. Massa,19a,19b G. Massaro,104 N. Massol,4 P. Mastrandrea,131a,131b A. Mastroberardino,36a,36b T. Masubuchi,154 M. Mathes,20 P. Matricon,114 H. Matsumoto,154 H. Matsunaga,154 T. Matsushita,66 C. Mattravers,117,d J. M. Maugain,29 J. Maurer,82 S. J. Maxfield,72 D. A. Maximov,106,g E. N. May,5 A. Mayne,138 R. Mazini,150 M. Mazur,20 M. Mazzanti,88a E. Mazzoni,121a,121b S. P. Mc Kee,86 A. McCarn,164 R. L. McCarthy,147 T. G. McCarthy,28 N. A. McCubbin,128 K. W. McFarlane,55 J. A. Mcfayden,138 H. McGlone,52 G. Mchedlidze,50b R. A. McLaren,29 T. Mclaughlan,17 S. J. McMahon,128 R. A. McPherson,168,k A. Meade,83 J. Mechnich,104 M. Mechtel,173 M. Medinnis,41 R. Meera-Lebbai,110 T. Meguro,115 R. Mehdiyev,92 S. Mehlhase,35 A. Mehta,72 K. Meier,57a B. Meirose,78 C. Melachrinos,30 B. R. Mellado Garcia,171 L. Mendoza Navas,161 Z. Meng,150,t A. Mengarelli,19a,19b S. Menke,98 C. Menot,29 E. Meoni,11 K. M. Mercurio,56 P. Mermod,48 L. Merola,101a,101b C. Meroni,88a F. S. Merritt,30 A. Messina,29 J. Metcalfe,102 A. S. Mete,63 C. Meyer,80 C. Meyer,30 J-P. Meyer,135 J. Meyer,172 J. Meyer,53 T. C. Meyer,29 W. T. Meyer,63 J. Miao,32d S. Michal,29 L. Micu,25a R. P. Middleton,128 S. Migas,72 L. Mijović,41 G. Mikenberg,170 M. Mikestikova,124 M. Mikuž,73 D. W. Miller,30 R. J. Miller,87 W. J. Mills,167 C. Mills,56 A. Milov,170 D. A. Milstead,145a,145b D. Milstein,170 A. A. Minaenko,127 M. Miñano Moya,166 I. A. Minashvili,64 A. I. Mincer,107 B. Mindur,37 M. Mineev,64 Y. Ming,171 L. M. Mir,11 G. Mirabelli,131a L. Miralles Verge,11 A. Misiejuk,75 J. Mitrevski,136 G. Y. Mitrofanov,127 V. A. Mitsou,166 S. Mitsui,65 P. S. Miyagawa,138 K. Miyazaki,66 J. U. Mjörnmark,78 T. Moa,145a,145b P. Mockett,137 S. Moed,56 V. Moeller,27 K. Mönig,41 N. Möser,20 S. Mohapatra,147 W. Mohr,47 S. Mohrdieck-Möck,98 A. M. Moisseev,127,a R. Moles-Valls,166 J. Molina-Perez,29 J. Monk,76 E. Monnier,82 S. Montesano,88a,88b F. Monticelli,69 S. Monzani,19a,19b R. W. Moore,2 G. F. Moorhead,85 C. Mora Herrera,48 A. Moraes,52 N. Morange,135 J. Morel,53 G. Morello,36a,36b D. Moreno,80 M. Moreno Llácer,166 P. Morettini,49a M. Morii,56 J. Morin,74 A. K. Morley,29 G. Mornacchi,29 S. V. Morozov,95 J. D. Morris,74 L. Morvaj,100 H. G. Moser,98 M. Mosidze,50b J. Moss,108 R. Mount,142 E. Mountricha,9,x S. V. Mouraviev,93 E. J. W. Moyse,83 M. Mudrinic,12b F. Mueller,57a J. Mueller,122 251801-10.

(11) PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. K. Mueller,20 T. A. Müller,97 T. Mueller,80 D. Muenstermann,29 A. Muir,167 Y. Munwes,152 W. J. Murray,128 I. Mussche,104 E. Musto,101a,101b A. G. Myagkov,127 M. Myska,124 J. Nadal,11 K. Nagai,159 K. Nagano,65 Y. Nagasaka,59 M. Nagel,98 A. M. Nairz,29 Y. Nakahama,29 K. Nakamura,154 T. Nakamura,154 I. Nakano,109 G. Nanava,20 A. Napier,160 R. Narayan,57b M. Nash,76,d N. R. Nation,21 T. Nattermann,20 T. Naumann,41 G. Navarro,161 H. A. Neal,86 E. Nebot,79 P. Yu. Nechaeva,93 A. Negri,118a,118b G. Negri,29 S. Nektarijevic,48 A. Nelson,162 S. Nelson,142 T. K. Nelson,142 S. Nemecek,124 P. Nemethy,107 A. A. Nepomuceno,23a M. Nessi,29,y M. S. Neubauer,164 A. Neusiedl,80 R. M. Neves,107 P. Nevski,24 P. R. Newman,17 V. Nguyen Thi Hong,135 R. B. Nickerson,117 R. Nicolaidou,135 L. Nicolas,138 B. Nicquevert,29 F. Niedercorn,114 J. Nielsen,136 T. Niinikoski,29 N. Nikiforou,34 A. Nikiforov,15 V. Nikolaenko,127 K. Nikolaev,64 I. Nikolic-Audit,77 K. Nikolics,48 K. Nikolopoulos,24 H. Nilsen,47 P. Nilsson,7 Y. Ninomiya,154 A. Nisati,131a T. Nishiyama,66 R. Nisius,98 L. Nodulman,5 M. Nomachi,115 I. Nomidis,153 M. Nordberg,29 B. Nordkvist,145a,145b P. R. Norton,128 J. Novakova,125 M. Nozaki,65 L. Nozka,112 I. M. Nugent,158a A.-E. Nuncio-Quiroz,20 G. Nunes Hanninger,85 T. Nunnemann,97 E. Nurse,76 T. Nyman,29 B. J. O’Brien,45 S. W. O’Neale,17,a D. C. O’Neil,141 V. O’Shea,52 L. B. Oakes,97 F. G. Oakham,28,e H. Oberlack,98 J. Ocariz,77 A. Ochi,66 S. Oda,154 S. Odaka,65 J. Odier,82 H. Ogren,60 A. Oh,81 S. H. Oh,44 C. C. Ohm,145a,145b T. Ohshima,100 H. Ohshita,139 T. Ohsugi,58 S. Okada,66 H. Okawa,162 Y. Okumura,100 T. Okuyama,154 A. Olariu,25a M. Olcese,49a A. G. Olchevski,64 M. Oliveira,123a,i D. Oliveira Damazio,24 E. Oliver Garcia,166 D. Olivito,119 A. Olszewski,38 J. Olszowska,38 C. Omachi,66 A. Onofre,123a,z P. U. E. Onyisi,30 C. J. Oram,158a M. J. Oreglia,30 Y. Oren,152 D. Orestano,133a,133b I. Orlov,106 C. Oropeza Barrera,52 R. S. Orr,157 B. Osculati,49a,49b R. Ospanov,119 C. Osuna,11 G. Otero y Garzon,26 J. P. Ottersbach,104 M. Ouchrif,134d E. A. Ouellette,168 F. Ould-Saada,116 A. Ouraou,135 Q. Ouyang,32a A. Ovcharova,14 M. Owen,81 S. Owen,138 V. E. Ozcan,18a N. Ozturk,7 A. Pacheco Pages,11 C. Padilla Aranda,11 S. Pagan Griso,14 E. Paganis,138 F. Paige,24 P. Pais,83 K. Pajchel,116 G. Palacino,158b C. P. Paleari,6 S. Palestini,29 D. Pallin,33 A. Palma,123a J. D. Palmer,17 Y. B. Pan,171 E. Panagiotopoulou,9 B. Panes,31a N. Panikashvili,86 S. Panitkin,24 D. Pantea,25a M. Panuskova,124 V. Paolone,122 A. Papadelis,145a Th. D. Papadopoulou,9 A. Paramonov,5 W. Park,24,aa M. A. Parker,27 F. Parodi,49a,49b J. A. Parsons,34 U. Parzefall,47 E. Pasqualucci,131a S. Passaggio,49a A. Passeri,133a F. Pastore,133a,133b Fr. Pastore,75 G. Pásztor,48,bb S. Pataraia,173 N. Patel,149 J. R. Pater,81 S. Patricelli,101a,101b T. Pauly,29 M. Pecsy,143a M. I. Pedraza Morales,171 S. V. Peleganchuk,106 H. Peng,32b R. Pengo,29 A. Penson,34 J. Penwell,60 M. Perantoni,23a K. Perez,34,cc T. Perez Cavalcanti,41 E. Perez Codina,11 M. T. Pérez Garcı́a-Estañ,166 V. Perez Reale,34 L. Perini,88a,88b H. Pernegger,29 R. Perrino,71a P. Perrodo,4 S. Persembe,3a A. Perus,114 V. D. Peshekhonov,64 K. Peters,29 B. A. Petersen,29 J. Petersen,29 T. C. Petersen,35 E. Petit,4 A. Petridis,153 C. Petridou,153 E. Petrolo,131a F. Petrucci,133a,133b D. Petschull,41 M. Petteni,141 R. Pezoa,31b A. Phan,85 P. W. Phillips,128 G. Piacquadio,29 E. Piccaro,74 M. Piccinini,19a,19b S. M. Piec,41 R. Piegaia,26 D. T. Pignotti,108 J. E. Pilcher,30 A. D. Pilkington,81 J. Pina,123a,c M. Pinamonti,163a,163c A. Pinder,117 J. L. Pinfold,2 J. Ping,32c B. Pinto,123a,c O. Pirotte,29 C. Pizio,88a,88b M. Plamondon,168 M.-A. Pleier,24 A. V. Pleskach,127 A. Poblaguev,24 S. Poddar,57a F. Podlyski,33 L. Poggioli,114 T. Poghosyan,20 M. Pohl,48 F. Polci,54 G. Polesello,118a A. Policicchio,36a,36b A. Polini,19a J. Poll,74 V. Polychronakos,24 D. M. Pomarede,135 D. Pomeroy,22 K. Pommès,29 L. Pontecorvo,131a B. G. Pope,87 G. A. Popeneciu,25a D. S. Popovic,12a A. Poppleton,29 X. Portell Bueso,29 C. Posch,21 G. E. Pospelov,98 S. Pospisil,126 I. N. Potrap,98 C. J. Potter,148 C. T. Potter,113 G. Poulard,29 J. Poveda,171 R. Prabhu,76 P. Pralavorio,82 A. Pranko,14 S. Prasad,56 R. Pravahan,7 S. Prell,63 K. Pretzl,16 L. Pribyl,29 D. Price,60 J. Price,72 L. E. Price,5 M. J. Price,29 D. Prieur,122 M. Primavera,71a K. Prokofiev,107 F. Prokoshin,31b S. Protopopescu,24 J. Proudfoot,5 X. Prudent,43 M. Przybycien,37 H. Przysiezniak,4 S. Psoroulas,20 E. Ptacek,113 E. Pueschel,83 J. Purdham,86 M. Purohit,24,aa P. Puzo,114 Y. Pylypchenko,62 J. Qian,86 Z. Qian,82 Z. Qin,41 A. Quadt,53 D. R. Quarrie,14 W. B. Quayle,171 F. Quinonez,31a M. Raas,103 V. Radescu,57b B. Radics,20 P. Radloff,113 T. Rador,18a F. Ragusa,88a,88b G. Rahal,176 A. M. Rahimi,108 D. Rahm,24 S. Rajagopalan,24 M. Rammensee,47 M. Rammes,140 A. S. Randle-Conde,39 K. Randrianarivony,28 P. N. Ratoff,70 F. Rauscher,97 M. Raymond,29 A. L. Read,116 D. M. Rebuzzi,118a,118b A. Redelbach,172 G. Redlinger,24 R. Reece,119 K. Reeves,40 A. Reichold,104 E. Reinherz-Aronis,152 A. Reinsch,113 I. Reisinger,42 D. Reljic,12a C. Rembser,29 Z. L. Ren,150 A. Renaud,114 P. Renkel,39 M. Rescigno,131a S. Resconi,88a B. Resende,135 P. Reznicek,97 R. Rezvani,157 A. Richards,76 R. Richter,98 E. Richter-Was,4,dd M. Ridel,77 M. Rijpstra,104 M. Rijssenbeek,147 A. Rimoldi,118a,118b L. Rinaldi,19a R. R. Rios,39 I. Riu,11 G. Rivoltella,88a,88b F. Rizatdinova,111 E. Rizvi,74 S. H. Robertson,84,k A. Robichaud-Veronneau,117 D. Robinson,27 J. E. M. Robinson,76 M. Robinson,113 A. Robson,52 J. G. Rocha de Lima,105 C. Roda,121a,121b D. Roda Dos Santos,29 D. Rodriguez,161 251801-11.

(12) PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. A. Roe,53 S. Roe,29 O. Røhne,116 V. Rojo,1 S. Rolli,160 A. Romaniouk,95 M. Romano,19a,19b V. M. Romanov,64 G. Romeo,26 E. Romero Adam,166 L. Roos,77 E. Ros,166 S. Rosati,131a K. Rosbach,48 A. Rose,148 M. Rose,75 G. A. Rosenbaum,157 E. I. Rosenberg,63 P. L. Rosendahl,13 O. Rosenthal,140 L. Rosselet,48 V. Rossetti,11 E. Rossi,131a,131b L. P. Rossi,49a M. Rotaru,25a I. Roth,170 J. Rothberg,137 D. Rousseau,114 C. R. Royon,135 A. Rozanov,82 Y. Rozen,151 X. Ruan,114,ee I. Rubinskiy,41 B. Ruckert,97 N. Ruckstuhl,104 V. I. Rud,96 C. Rudolph,43 G. Rudolph,61 F. Rühr,6 F. Ruggieri,133a,133b A. Ruiz-Martinez,63 V. Rumiantsev,90,a L. Rumyantsev,64 K. Runge,47 Z. Rurikova,47 N. A. Rusakovich,64 D. R. Rust,60 J. P. Rutherfoord,6 C. Ruwiedel,14 P. Ruzicka,124 Y. F. Ryabov,120 V. Ryadovikov,127 P. Ryan,87 M. Rybar,125 G. Rybkin,114 N. C. Ryder,117 S. Rzaeva,10 A. F. Saavedra,149 I. Sadeh,152 H. F-W. Sadrozinski,136 R. Sadykov,64 F. Safai Tehrani,131a H. Sakamoto,154 G. Salamanna,74 A. Salamon,132a M. Saleem,110 D. Salihagic,98 A. Salnikov,142 J. Salt,166 B. M. Salvachua Ferrando,5 D. Salvatore,36a,36b F. Salvatore,148 A. Salvucci,103 A. Salzburger,29 D. Sampsonidis,153 B. H. Samset,116 A. Sanchez,101a,101b H. Sandaker,13 H. G. Sander,80 M. P. Sanders,97 M. Sandhoff,173 T. Sandoval,27 C. Sandoval,161 R. Sandstroem,98 S. Sandvoss,173 D. P. C. Sankey,128 A. Sansoni,46 C. Santamarina Rios,84 C. Santoni,33 R. Santonico,132a,132b H. Santos,123a J. G. Saraiva,123a T. Sarangi,171 E. Sarkisyan-Grinbaum,7 F. Sarri,121a,121b G. Sartisohn,173 O. Sasaki,65 N. Sasao,67 I. Satsounkevitch,89 G. Sauvage,4 E. Sauvan,4 J. B. Sauvan,114 P. Savard,157,e V. Savinov,122 D. O. Savu,29 L. Sawyer,24,m D. H. Saxon,52 L. P. Says,33 C. Sbarra,19a A. Sbrizzi,19a,19b O. Scallon,92 D. A. Scannicchio,162 M. Scarcella,149 J. Schaarschmidt,114 P. Schacht,98 U. Schäfer,80 S. Schaepe,20 S. Schaetzel,57b A. C. Schaffer,114 D. Schaile,97 R. D. Schamberger,147 A. G. Schamov,106 V. Scharf,57a V. A. Schegelsky,120 D. Scheirich,86 M. Schernau,162 M. I. Scherzer,34 C. Schiavi,49a,49b J. Schieck,97 M. Schioppa,36a,36b S. Schlenker,29 J. L. Schlereth,5 E. Schmidt,47 K. Schmieden,20 C. Schmitt,80 S. Schmitt,57b M. Schmitz,20 A. Schöning,57b M. Schott,29 D. Schouten,158a J. Schovancova,124 M. Schram,84 C. Schroeder,80 N. Schroer,57c S. Schuh,29 G. Schuler,29 J. Schultes,173 H.-C. Schultz-Coulon,57a H. Schulz,15 J. W. Schumacher,20 M. Schumacher,47 B. A. Schumm,136 Ph. Schune,135 C. Schwanenberger,81 A. Schwartzman,142 Ph. Schwemling,77 R. Schwienhorst,87 R. Schwierz,43 J. Schwindling,135 T. Schwindt,20 M. Schwoerer,4 W. G. Scott,128 J. Searcy,113 G. Sedov,41 E. Sedykh,120 E. Segura,11 S. C. Seidel,102 A. Seiden,136 F. Seifert,43 J. M. Seixas,23a G. Sekhniaidze,101a K. E. Selbach,45 D. M. Seliverstov,120 B. Sellden,145a G. Sellers,72 M. Seman,143b N. Semprini-Cesari,19a,19b C. Serfon,97 L. Serin,114 R. Seuster,98 H. Severini,110 M. E. Sevior,85 A. Sfyrla,29 E. Shabalina,53 M. Shamim,113 L. Y. Shan,32a J. T. Shank,21 Q. T. Shao,85 M. Shapiro,14 P. B. Shatalov,94 L. Shaver,6 K. Shaw,163a,163c D. Sherman,174 P. Sherwood,76 A. Shibata,107 H. Shichi,100 S. Shimizu,29 M. Shimojima,99 T. Shin,55 M. Shiyakova,64 A. Shmeleva,93 M. J. Shochet,30 D. Short,117 S. Shrestha,63 M. A. Shupe,6 P. Sicho,124 A. Sidoti,131a F. Siegert,47 Dj. Sijacki,12a O. Silbert,170 J. Silva,123a,c Y. Silver,152 D. Silverstein,142 S. B. Silverstein,145a V. Simak,126 O. Simard,135 Lj. Simic,12a S. Simion,114 B. Simmons,76 M. Simonyan,35 P. Sinervo,157 N. B. Sinev,113 V. Sipica,140 G. Siragusa,172 A. Sircar,24 A. N. Sisakyan,64 S. Yu. Sivoklokov,96 J. Sjölin,145a,145b T. B. Sjursen,13 L. A. Skinnari,14 H. P. Skottowe,56 K. Skovpen,106 P. Skubic,110 N. Skvorodnev,22 M. Slater,17 T. Slavicek,126 K. Sliwa,160 J. Sloper,29 V. Smakhtin,170 S. Yu. Smirnov,95 L. N. Smirnova,96 O. Smirnova,78 B. C. Smith,56 D. Smith,142 K. M. Smith,52 M. Smizanska,70 K. Smolek,126 A. A. Snesarev,93 S. W. Snow,81 J. Snow,110 J. Snuverink,104 S. Snyder,24 M. Soares,123a R. Sobie,168,k J. Sodomka,126 A. Soffer,152 C. A. Solans,166 M. Solar,126 J. Solc,126 E. Soldatov,95 U. Soldevila,166 E. Solfaroli Camillocci,131a,131b A. A. Solodkov,127 O. V. Solovyanov,127 N. Soni,2 V. Sopko,126 B. Sopko,126 M. Sosebee,7 R. Soualah,163a,163c A. Soukharev,106 S. Spagnolo,71a,71b F. Spanò,75 R. Spighi,19a G. Spigo,29 F. Spila,131a,131b R. Spiwoks,29 M. Spousta,125 T. Spreitzer,157 B. Spurlock,7 R. D. St. Denis,52 T. Stahl,140 J. Stahlman,119 R. Stamen,57a E. Stanecka,38 R. W. Stanek,5 C. Stanescu,133a S. Stapnes,116 E. A. Starchenko,127 J. Stark,54 P. Staroba,124 P. Starovoitov,90 A. Staude,97 P. Stavina,143a G. Stavropoulos,14 G. Steele,52 P. Steinbach,43 P. Steinberg,24 I. Stekl,126 B. Stelzer,141 H. J. Stelzer,87 O. Stelzer-Chilton,158a H. Stenzel,51 S. Stern,98 K. Stevenson,74 G. A. Stewart,29 J. A. Stillings,20 M. C. Stockton,84 K. Stoerig,47 G. Stoicea,25a S. Stonjek,98 P. Strachota,125 A. R. Stradling,7 A. Straessner,43 J. Strandberg,146 S. Strandberg,145a,145b A. Strandlie,116 M. Strang,108 E. Strauss,142 M. Strauss,110 P. Strizenec,143b R. Ströhmer,172 D. M. Strom,113 J. A. Strong,75,a R. Stroynowski,39 J. Strube,128 B. Stugu,13 I. Stumer,24,a J. Stupak,147 P. Sturm,173 N. A. Styles,41 D. A. Soh,150,v D. Su,142 HS. Subramania,2 A. Succurro,11 Y. Sugaya,115 T. Sugimoto,100 C. Suhr,105 K. Suita,66 M. Suk,125 V. V. Sulin,93 S. Sultansoy,3d T. Sumida,67 X. Sun,54 J. E. Sundermann,47 K. Suruliz,138 S. Sushkov,11 G. Susinno,36a,36b M. R. Sutton,148 Y. Suzuki,65 Y. Suzuki,66 M. Svatos,124 Yu. M. Sviridov,127 S. Swedish,167 I. Sykora,143a T. Sykora,125 B. Szeless,29 J. Sánchez,166 D. Ta,104 K. Tackmann,41 A. Taffard,162 R. Tafirout,158a 251801-12.

(13) PRL 108, 251801 (2012). PHYSICAL REVIEW LETTERS. week ending 22 JUNE 2012. N. Taiblum,152 Y. Takahashi,100 H. Takai,24 R. Takashima,68 H. Takeda,66 T. Takeshita,139 Y. Takubo,65 M. Talby,82 A. Talyshev,106,g M. C. Tamsett,24 J. Tanaka,154 R. Tanaka,114 S. Tanaka,130 S. Tanaka,65 Y. Tanaka,99 A. J. Tanasijczuk,141 K. Tani,66 N. Tannoury,82 G. P. Tappern,29 S. Tapprogge,80 D. Tardif,157 S. Tarem,151 F. Tarrade,28 G. F. Tartarelli,88a P. Tas,125 M. Tasevsky,124 E. Tassi,36a,36b M. Tatarkhanov,14 Y. Tayalati,134d C. Taylor,76 F. E. Taylor,91 G. N. Taylor,85 W. Taylor,158b M. Teinturier,114 M. Teixeira Dias Castanheira,74 P. Teixeira-Dias,75 K. K. Temming,47 H. Ten Kate,29 P. K. Teng,150 S. Terada,65 K. Terashi,154 J. Terron,79 M. Testa,46 R. J. Teuscher,157,k J. Thadome,173 J. Therhaag,20 T. Theveneaux-Pelzer,77 M. Thioye,174 S. Thoma,47 J. P. Thomas,17 E. N. Thompson,34 P. D. Thompson,17 P. D. Thompson,157 A. S. Thompson,52 E. Thomson,119 M. Thomson,27 R. P. Thun,86 F. Tian,34 M. J. Tibbetts,14 T. Tic,124 V. O. Tikhomirov,93 Y. A. Tikhonov,106,g S. Timoshenko,95 P. Tipton,174 F. J. Tique Aires Viegas,29 S. Tisserant,82 B. Toczek,37 T. Todorov,4 S. Todorova-Nova,160 B. Toggerson,162 J. Tojo,65 S. Tokár,143a K. Tokunaga,66 K. Tokushuku,65 K. Tollefson,87 M. Tomoto,100 L. Tompkins,30 K. Toms,102 G. Tong,32a A. Tonoyan,13 C. Topfel,16 N. D. Topilin,64 I. Torchiani,29 E. Torrence,113 H. Torres,77 E. Torró Pastor,166 J. Toth,82,bb F. Touchard,82 D. R. Tovey,138 T. Trefzger,172 L. Tremblet,29 A. Tricoli,29 I. M. Trigger,158a S. Trincaz-Duvoid,77 T. N. Trinh,77 M. F. Tripiana,69 W. Trischuk,157 A. Trivedi,24,aa B. Trocmé,54 C. Troncon,88a M. Trottier-McDonald,141 M. Trzebinski,38 A. Trzupek,38 C. Tsarouchas,29 J. C-L. Tseng,117 M. Tsiakiris,104 P. V. Tsiareshka,89 D. Tsionou,4,ff G. Tsipolitis,9 V. Tsiskaridze,47 E. G. Tskhadadze,50a I. I. Tsukerman,94 V. Tsulaia,14 J.-W. Tsung,20 S. Tsuno,65 D. Tsybychev,147 A. Tua,138 A. Tudorache,25a V. Tudorache,25a J. M. Tuggle,30 M. Turala,38 D. Turecek,126 I. Turk Cakir,3e E. Turlay,104 R. Turra,88a,88b P. M. Tuts,34 A. Tykhonov,73 M. Tylmad,145a,145b M. Tyndel,128 G. Tzanakos,8 K. Uchida,20 I. Ueda,154 R. Ueno,28 M. Ugland,13 M. Uhlenbrock,20 M. Uhrmacher,53 F. Ukegawa,159 G. Unal,29 D. G. Underwood,5 A. Undrus,24 G. Unel,162 Y. Unno,65 D. Urbaniec,34 G. Usai,7 M. Uslenghi,118a,118b L. Vacavant,82 V. Vacek,126 B. Vachon,84 S. Vahsen,14 J. Valenta,124 P. Valente,131a S. Valentinetti,19a,19b S. Valkar,125 E. Valladolid Gallego,166 S. Vallecorsa,151 J. A. Valls Ferrer,166 H. van der Graaf,104 E. van der Kraaij,104 R. Van Der Leeuw,104 E. van der Poel,104 D. van der Ster,29 N. van Eldik,83 P. van Gemmeren,5 Z. van Kesteren,104 I. van Vulpen,104 M. Vanadia,98 W. Vandelli,29 G. Vandoni,29 A. Vaniachine,5 P. Vankov,41 F. Vannucci,77 F. Varela Rodriguez,29 R. Vari,131a E. W. Varnes,6 D. Varouchas,14 A. Vartapetian,7 K. E. Varvell,149 V. I. Vassilakopoulos,55 F. Vazeille,33 G. Vegni,88a,88b J. J. Veillet,114 C. Vellidis,8 F. Veloso,123a R. Veness,29 S. Veneziano,131a A. Ventura,71a,71b D. Ventura,137 M. Venturi,47 N. Venturi,157 V. Vercesi,118a M. Verducci,137 W. Verkerke,104 J. C. Vermeulen,104 A. Vest,43 M. C. Vetterli,141,e I. Vichou,164 T. Vickey,144b,gg O. E. Vickey Boeriu,144b G. H. A. Viehhauser,117 S. Viel,167 M. Villa,19a,19b M. Villaplana Perez,166 E. Vilucchi,46 M. G. Vincter,28 E. Vinek,29 V. B. Vinogradov,64 M. Virchaux,135,a J. Virzi,14 O. Vitells,170 M. Viti,41 I. Vivarelli,47 F. Vives Vaque,2 S. Vlachos,9 D. Vladoiu,97 M. Vlasak,126 N. Vlasov,20 A. Vogel,20 P. Vokac,126 G. Volpi,46 M. Volpi,85 G. Volpini,88a H. von der Schmitt,98 J. von Loeben,98 H. von Radziewski,47 E. von Toerne,20 V. Vorobel,125 A. P. Vorobiev,127 V. Vorwerk,11 M. Vos,166 R. Voss,29 T. T. Voss,173 J. H. Vossebeld,72 N. Vranjes,12a M. Vranjes Milosavljevic,104 V. Vrba,124 M. Vreeswijk,104 T. Vu Anh,80 R. Vuillermet,29 I. Vukotic,114 W. Wagner,173 P. Wagner,119 H. Wahlen,173 J. Wakabayashi,100 J. Walbersloh,42 S. Walch,86 J. Walder,70 R. Walker,97 W. Walkowiak,140 R. Wall,174 P. Waller,72 C. Wang,44 H. Wang,171 H. Wang,32b,hh J. Wang,150 J. Wang,54 J. C. Wang,137 R. Wang,102 S. M. Wang,150 A. Warburton,84 C. P. Ward,27 M. Warsinsky,47 P. M. Watkins,17 A. T. Watson,17 I. J. Watson,149 M. F. Watson,17 G. Watts,137 S. Watts,81 A. T. Waugh,149 B. M. Waugh,76 M. Weber,128 M. S. Weber,16 P. Weber,53 A. R. Weidberg,117 P. Weigell,98 J. Weingarten,53 C. Weiser,47 H. Wellenstein,22 P. S. Wells,29 M. Wen,46 T. Wenaus,24 S. Wendler,122 Z. Weng,150,v T. Wengler,29 S. Wenig,29 N. Wermes,20 M. Werner,47 P. Werner,29 M. Werth,162 M. Wessels,57a C. Weydert,54 K. Whalen,28 S. J. Wheeler-Ellis,162 S. P. Whitaker,21 A. White,7 M. J. White,85 S. R. Whitehead,117 D. Whiteson,162 D. Whittington,60 F. Wicek,114 D. Wicke,173 F. J. Wickens,128 W. Wiedenmann,171 M. Wielers,128 P. Wienemann,20 C. Wiglesworth,74 L. A. M. Wiik-Fuchs,47 P. A. Wijeratne,76 A. Wildauer,166 M. A. Wildt,41,r I. Wilhelm,125 H. G. Wilkens,29 J. Z. Will,97 E. Williams,34 H. H. Williams,119 W. Willis,34 S. Willocq,83 J. A. Wilson,17 M. G. Wilson,142 A. Wilson,86 I. Wingerter-Seez,4 S. Winkelmann,47 F. Winklmeier,29 M. Wittgen,142 M. W. Wolter,38 H. Wolters,123a,i W. C. Wong,40 G. Wooden,86 B. K. Wosiek,38 J. Wotschack,29 M. J. Woudstra,83 K. W. Wozniak,38 K. Wraight,52 C. Wright,52 M. Wright,52 B. Wrona,72 S. L. Wu,171 X. Wu,48 Y. Wu,32b,ii E. Wulf,34 R. Wunstorf,42 B. M. Wynne,45 S. Xella,35 M. Xiao,135 S. Xie,47 Y. Xie,32a C. Xu,32b,x D. Xu,138 G. Xu,32a B. Yabsley,149 S. Yacoob,144b M. Yamada,65 H. Yamaguchi,154 A. Yamamoto,65 K. Yamamoto,63 S. Yamamoto,154 T. Yamamura,154 T. Yamanaka,154 J. Yamaoka,44 T. Yamazaki,154 Y. Yamazaki,66 Z. Yan,21 H. Yang,86 U. K. Yang,81 251801-13.

(14) PHYSICAL REVIEW LETTERS. PRL 108, 251801 (2012). week ending 22 JUNE 2012. Y. Yang,60 Y. Yang,32a Z. Yang,145a,145b S. Yanush,90 Y. Yao,14 Y. Yasu,65 G. V. Ybeles Smit,129 J. Ye,39 S. Ye,24 M. Yilmaz,3c R. Yoosoofmiya,122 K. Yorita,169 R. Yoshida,5 C. Young,142 S. Youssef,21 D. Yu,24 J. Yu,7 J. Yu,111 L. Yuan,32a,jj A. Yurkewicz,105 B. Zabinski,38 V. G. Zaets,127 R. Zaidan,62 A. M. Zaitsev,127 Z. Zajacova,29 L. Zanello,131a,131b P. Zarzhitsky,39 A. Zaytsev,106 C. Zeitnitz,173 M. Zeller,174 M. Zeman,124 A. Zemla,38 C. Zendler,20 O. Zenin,127 T. Ženiš,143a Z. Zinonos,121a,121b S. Zenz,14 D. Zerwas,114 G. Zevi della Porta,56 Z. Zhan,32d D. Zhang,32b,ff H. Zhang,87 J. Zhang,5 X. Zhang,32d Z. Zhang,114 L. Zhao,107 T. Zhao,137 Z. Zhao,32b A. Zhemchugov,64 S. Zheng,32a J. Zhong,117 B. Zhou,86 N. Zhou,162 Y. Zhou,150 C. G. Zhu,32d H. Zhu,41 J. Zhu,86 Y. Zhu,32b X. Zhuang,97 V. Zhuravlov,98 D. Zieminska,60 R. Zimmermann,20 S. Zimmermann,20 S. Zimmermann,47 M. Ziolkowski,140 R. Zitoun,4 L. Živković,34 V. V. Zmouchko,127,a G. Zobernig,171 A. Zoccoli,19a,19b Y. Zolnierowski,4 A. Zsenei,29 M. zur Nedden,15 V. Zutshi,105 and L. Zwalinski29 (ATLAS Collaboration) 1 University at Albany, Albany, New York, USA Department of Physics, University of Alberta, Edmonton, Alberta, Canada 3a Department of Physics, Ankara University, Ankara, Turkey 3b Department of Physics, Dumlupinar University, Kutahya, Turkey 3c Department of Physics, Gazi University, Ankara, Turkey 3d Division of Physics, TOBB University of Economics and Technology, Ankara, Turkey 3e Turkish Atomic Energy Authority, Ankara, Turkey 4 LAPP, CNRS/IN2P3 and Université de Savoie, Annecy-le-Vieux, France 5 High Energy Physics Division, Argonne National Laboratory, Argonne, Illinois, USA 6 Department of Physics, University of Arizona, Tucson, Arizona, USA 7 Department of Physics, The University of Texas at Arlington, Arlington, Texas, USA 8 Physics Department, University of Athens, Athens, Greece 9 Physics Department, National Technical University of Athens, Zografou, Greece 10 Institute of Physics, Azerbaijan Academy of Sciences, Baku, Azerbaijan 11 Institut de Fı́sica d’Altes Energies and Departament de Fı́sica de la Universitat Autònoma de Barcelona and ICREA, Barcelona, Spain 12a Institute of Physics, University of Belgrade, Belgrade, Serbia 12b Vinca Institute of Nuclear Sciences, University of Belgrade, Belgrade, Serbia 13 Department for Physics and Technology, University of Bergen, Bergen, Norway 14 Physics Division, Lawrence Berkeley National Laboratory and University of California, Berkeley, California, USA 15 Department of Physics, Humboldt University, Berlin, Germany 16 Albert Einstein Center for Fundamental Physics and Laboratory for High Energy Physics, University of Bern, Bern, Switzerland 17 School of Physics and Astronomy, University of Birmingham, Birmingham, United Kingdom 18a Department of Physics, Bogazici University, Istanbul, Turkey 18b Division of Physics, Dogus University, Istanbul, Turkey 18c Department of Physics Engineering, Gaziantep University, Gaziantep, Turkey 18d Department of Physics, Istanbul Technical University, Istanbul, Turkey 19a INFN Sezione di Bologna, Italy 19b Dipartimento di Fisica, Università di Bologna, Bologna, Italy 20 Physikalisches Institut, University of Bonn, Bonn, Germany 21 Department of Physics, Boston University, Boston, Massachusetts, USA 22 Department of Physics, Brandeis University, Waltham, Massachusetts, USA 23a Universidade Federal do Rio De Janeiro COPPE/EE/IF, Rio de Janeiro, Brazil 23b Federal University of Juiz de Fora (UFJF), Juiz de Fora, Brazil 23c Federal University of Sao Joao del Rei (UFSJ), Sao Joao del Rei, Brazil 23d Instituto de Fisica, Universidade de Sao Paulo, Sao Paulo, Brazil 24 Physics Department, Brookhaven National Laboratory, Upton, New York, USA 25a National Institute of Physics and Nuclear Engineering, Bucharest, Romania 25b University Politehnica Bucharest, Bucharest, Romania 25c West University in Timisoara, Timisoara, Romania 26 Departamento de Fı́sica, Universidad de Buenos Aires, Buenos Aires, Argentina 27 Cavendish Laboratory, University of Cambridge, Cambridge, United Kingdom 28 Department of Physics, Carleton University, Ottawa, Ontario, Canada 29 CERN, Geneva, Switzerland 30 Enrico Fermi Institute, University of Chicago, Chicago, Illinois, USA 2. 251801-14.